Database Triggers

• An Introduction to Triggers

• Parts of a Trigger

• Trigger ExecutionYou may fire when you are ready, Gridley.George Dewey: at the battle of Manila BayThis chapter discusses database triggers; that is, procedures that are stored in thedatabase and implicitly executed ("fired") when a table is modified. This chapterincludes: • An Introduction to Triggers

• Parts of a Trigger

• Triggers ExecutionIf you are using Trusted Oracle, see the Trusted Oracle7 Server Administrator'sGuide.An Introduction to Triggers - Oracle allows you to define procedures that are implicitly executed when an INSERT, UPDATE, or DELETE statement is issued against the associated table. - These procedures are called database triggers. - Triggers are similar to stored procedures, discussed in Chapter 14, "Procedures and Packages". - A trigger can include SQL and PL/SQL statements to execute as a unit and can invoke stored procedures. - However, procedures and triggers differ in the way that they are invoked. While a procedure is explicitly executed by a user, application, or trigger, one or more triggers are implicitly fired (executed) by Oracle when a triggering INSERT, UPDATE, or DELETE statement is issued, no matter which user is connected or which application is being used.For example, Figure 15 - 1 shows a database application with some SQL statementsthat implicitly fire several triggers stored in the database.Figure 15 - 1. Triggers - Notice that triggers are stored in the database separately from their associated tables. - Triggers can be defined only on tables, not on views. - However, triggers on the base table(s) of a view are fired if an INSERT, UPDATE, or DELETE statement is issued against a view.How Triggers Are Used - In many cases, triggers supplement the standard capabilities of Oracle to provide a highly customized database management system. - For example, a trigger can permit DML operations against a table only if they are issued during regular business hours. - The standard security features of Oracle, roles and privileges, govern which users can submit DML statements against the table. - In addition, the trigger further restricts DML operations to occur only at certain times during weekdays. - This is just one way that you can use triggers to customize information management in an Oracle database.In addition, triggers are commonly used to • automatically generate derived column values

• prevent invalid transactions

• enforce complex security authorizations

• enforce referential integrity across nodes in a distributed database

• enforce complex business rules

• provide transparent event logging

• provide sophisticated auditing

• maintain synchronous table replicates

• gather statistics on table access

A Cautionary Note about Trigger Use

- When a trigger is fired, a SQL statement within its trigger action potentially can fire other triggers, as illustrated in Figure 15 - 2. - When a statement in a trigger body causes another trigger to be fired, the triggers are said to be cascading.

Figure 15 - 2. Cascading Triggers

- While triggers are useful for customizing a database, you should only use triggers when necessary. - The excessive use of triggers can result in complex interdependences, which may be difficult to maintain in a large application.Database Triggers vs. Oracle Forms Triggers - Oracle Forms can also define, store, and execute triggers. - However, do not confuse Oracle Forms triggers with the database triggers discussed in this chapter. - Database triggers are defined on a table, stored in the associated database, and executed as a result of an INSERT, UPDATE, or DELETE statement being issued against a table, no matter which user or application issues the statement. - Oracle Forms triggers are part of an Oracle Forms application and are fired only when a specific trigger point is executed within a specific Oracle Forms application. - SQL statements within an Oracle Forms application, as with any database application, can implicitly cause the firing of any associated database trigger.Triggers vs. Declarative Integrity Constraints - Triggers and declarative integrity constraints can both be used to constrain data input. - However, triggers and integrity constraints have significant differences. - A declarative integrity constraint is a statement about the database that is never false while the constraint is enabled. - A constraint applies to existing data in the table and any statement that manipulates the table. - Triggers constrain what transactions can do. - A trigger does not apply to data loaded before the definition of the trigger. Therefore, it does not guarantee all data in a table conforms to its rules. - A trigger enforces transitional constraints; that is, a trigger only enforces a constraint at the time that the data changes. - Therefore, a constraint such as "make sure that the delivery date is at least seven days from today" should be enforced by a trigger, not a declarative integrity constraint. - In evaluating triggers that contain SQL functions that have NLS parameters as arguments (for example, TO_CHAR, TO_DATE, and TO_NUMBER), the default values for these parameters are taken from the NLS parameters currently in effect for the session. - You can override the default values by specifying NLS parameters explicitly in such functions when you create a trigger.Parts of a TriggerA trigger has three basic parts: • a triggering event or statement

• a trigger restriction

• a trigger actionFigure 15 - 3 represents each of these parts of a trigger and is not meant to show exactsyntax. Each part of a trigger is explained in greater detail in the following sections.

Figure 15 - 3. The REORDER Trigger

Triggering Event or Statement - A triggering event or statement is the SQL statement that causes a trigger to be fired. - A triggering event can be an INSERT, UPDATE, or DELETE statement on a table.For example, in Figure 15 - 3, the triggering statement is. . . UPDATE OF parts_on_hand ON inventory . . .which means that when the PARTS_ON_HAND column of a row in theINVENTORY table is updated, fire the trigger. - Note that when the triggering event is an UPDATE statement, you can include a column list to identify which columns must be updated to fire the trigger. - Because INSERT and DELETE statements affect entire rows of information, a column list cannot be specified for these options. - A triggering event can specify multiple DML statements, as in . . . INSERT OR UPDATE OR DELETE OF inventory . . . which means that when an INSERT, UPDATE, or DELETE statement is issued against the INVENTORY table, fire the trigger. - When multiple types of DML statements can fire a trigger, conditional predicates can be used to detect the type of triggering statement. - Therefore, a single trigger can be created that executes different code based on the type of statement that fired the trigger.Trigger Restriction - A trigger restriction specifies a Boolean (logical) expression that must be TRUE for the trigger to fire. - The trigger action is not executed if the trigger restriction evaluates to FALSE or UNKNOWN. - A trigger restriction is an option available for triggers that are fired for each row. - Its function is to control the execution of a trigger conditionally. - You specify a trigger restriction using a WHEN clause. For example, the REORDER trigger in Figure 15 - 3 has a trigger restriction. The trigger is fired by an UPDATE statement affecting the PARTS_ON_HAND column of the INVENTORY table, but the trigger action only fires if the following expression is TRUE:new.parts_on_hand < new.reorder_point

Trigger Action - A trigger action is the procedure (PL/SQL block) that contains the SQL statements and PL/SQL code to be executed when a triggering statement is issued and the trigger restriction evaluates to TRUE. - Similar to stored procedures, a trigger action can contain SQL and PL/SQL statements, define PL/SQL language constructs (variables, constants, cursors, exceptions, and so on), and call stored procedures. - Additionally, for row trigger, the statements in a trigger action have access to column values (new and old) of the current row being processed by the trigger. - Two correlation names provide access to the old and new values for each column.Types of Triggers - When you define a trigger, you can specify the number of times the trigger action is to be executed: once for every row affected by the triggering statement (such as might be fired by an UPDATE statement that updates many rows), or once for the triggering statement, no matter how many rows it affects.Row Triggers - A row trigger is fired each time the table is affected by the triggering statement. - For example, if an UPDATE statement updates multiple rows of a table, a row trigger is fired once for each row affected by the UPDATE statement. - If a triggering statement affects no rows, a row trigger is not executed at all. - Row triggers are useful if the code in the trigger action depends on data provided by the triggering statement or rows that are affected. - For example, Figure 15 - 3 illustrates a row trigger that uses the values of each row affected by the triggering statement.Statement Triggers - A statement trigger is fired once on behalf of the triggering statement, regardless of the number of rows in the table that the triggering statement affects (even if no rows are affected). - For example, if a DELETE statement deletes several rows from a table, a statement-level DELETE trigger is fired only once, regardless of how many rows are deleted from the table. - Statement triggers are useful if the code in the trigger action does not depend on the data provided by the triggering statement or the rows affected. - For example, if a trigger makes a complex security check on the current time or user, or if a trigger generates a single audit record based on the type of triggering statement, a statement trigger is used.BEFORE vs. AFTER Triggers - When defining a trigger, you can specify the trigger timing. - That is, you can specify whether the trigger action is to be executed before or after the triggering statement. - BEFORE and AFTER apply to both statement and row triggers.BEFORE Triggers BEFORE triggers execute the trigger action before the triggeringstatement. This type of trigger is commonly used in the following situations: • BEFORE triggers are used when the trigger action should determine whether the triggering statement should be allowed to complete. By using a BEFORE trigger for this purpose, you can eliminate unnecessary processing of the triggering statement and its eventual rollback in cases where an exception is raised in the trigger action. • BEFORE triggers are used to derive specific column values before completing a triggering INSERT or UPDATE statement.AFTER Triggers AFTER triggers execute the trigger action after the triggeringstatement is executed. AFTER triggers are used in the following situations: • AFTER triggers are used when you want the triggering statement to complete before executing the trigger action. • If a BEFORE trigger is already present, an AFTER trigger can perform different actions on the same triggering statement.CombinationsUsing the options listed in the previous two sections, you can create four types oftriggers: • BEFORE statement trigger Before executing the triggering statement, the trigger action is executed. • BEFORE row trigger Before modifying each row affected by the triggering statement and before checking appropriate integrity constraints, the trigger action is executed provided that the trigger restriction was not violated. • AFTER statement trigger After executing the triggering statement and applying any deferred integrity constraints, the trigger action is executed. • AFTER row trigger After modifying each row affected by the triggering statement and possibly applying appropriate integrity constraints, the trigger action is executed for the current row provided the trigger restriction was not violated. Unlike BEFORE row triggers, AFTER row triggers lock rows.- You can have multiple triggers of the same type for the same statement for any given table.- For example you may have two BEFORE STATEMENT triggers for UPDATE statements on the EMP table.- Multiple triggers of the same type permit modular installation of applications that have triggers on the same tables.- Also, Oracle snapshot logs use AFTER ROW triggers, so you can design your own AFTER ROW trigger in addition to the Oracle-defined AFTER ROW trigger.- You can create as many triggers of the preceding different types as you need for each type of DML statement (INSERT, UPDATE, or DELETE).- For example, suppose you have a table, SAL, and you want to know when the table is being accessed and the types of queries being issued.- Figure 15 - 4 contains a sample package and trigger that tracks this information by hour and type of action (for example, UPDATE, DELETE, or INSERT) on table SAL.- A global session variable, STAT.ROWCNT, is initialized to zero by a BEFORE statement trigger, then it is increased each time the row trigger is executed, and finally the statistical information is saved in the table STAT_TAB by the AFTER statement trigger.DROP TABLE stat_tab;CREATE TABLE stat_tab(utype CHAR(8), rowcnt INTEGER, uhour INTEGER);

CREATE OR REPLACE PACKAGE stat IS

rowcnt INTEGER;END;/

CREATE TRIGGER bt BEFORE UPDATE OR DELETE OR INSERT ON

salBEGIN stat.rowcnt := 0;END;/

CREATE TRIGGER rt BEFORE UPDATE OR DELETE OR INSERT ON

salFOR EACH ROW BEGIN stat.rowcnt := stat.rowcnt + 1;END;/

CREATE TRIGGER at AFTER UPDATE OR DELETE OR INSERT ON sal

DECLARE typ CHAR(8); hour NUMBER;BEGIN IF updating THEN typ := 'update'; END IF; IF deleting THEN typ := 'delete'; END IF; IF inserting THEN typ := 'insert'; END IF;

hour := TRUNC((SYSDATE - TRUNC(SYSDATE)) * 24);

EXCEPTION WHEN dup_val_on_index THEN UPDATE stat_tab SET rowcnt = rowcnt + stat.rowcnt WHERE utype = typ AND uhour = hour;END;/Trigger ExecutionA trigger can be in either of two distinct modes:enabledAn enabled trigger executes its trigger action if a triggering statement is issued andthe trigger restriction (if any) evaluates to TRUE.disabledA disabled trigger does not execute its trigger action, even if a triggering statement isissued and the trigger restriction (if any) would evaluate to TRUE.For enabled triggers, Oracle automatically • executes triggers of each type in a planned firing sequence when more than one trigger is fired by a single SQL statement • performs integrity constraint checking at a set point in time with respect to the different types of triggers and guarantees that triggers cannot compromise integrity constraints • provides read-consistent views for queries and constraints

• manages the dependencies among triggers and objects referenced in the code of the trigger action • uses two-phase commit if a trigger updates remote tables in a distributed database • if more than one trigger of the same type for a given statement exists, Oracle fires each of those triggers in an unspecified orderThe Execution Model for Triggers and Integrity Constraint Checking- A single SQL statement can potentially fire up to four types of triggers: BEFORE row triggers, BEFORE statement triggers, AFTER row triggers, and AFTER statement triggers.- A triggering statement or a statement within a trigger can cause one or more integrity constraints to be checked. Also, triggers can contain statements that cause other triggers to fire (cascading triggers).- Oracle uses the following execution model to maintain the proper firing sequence of multiple triggers and constraint checking:1. Execute all BEFORE statement triggers that apply tothe statement.2. Loop for each row affected by the SQL statement.a. Execute all BEFORE row triggers that apply to thestatement.b. Lock and change row, and perform integrity constraintchecking (The lock is not released until thetransaction is committed.)c. Execute all AFTER row triggers that apply to thestatement.3. Complete deferred integrity constraint checking.4. Execute all AFTER statement triggers that apply to thestatement.- The definition of the execution model is recursive.- For example, a given SQL statement can cause a BEFORE row trigger to be fired and an integrity constraint to be checked.- That BEFORE row trigger, in turn, might perform an update that causes an integrity constraint to be checked and an AFTER statement trigger to be fired.- The AFTER statement trigger causes an integrity constraint to be checked. In this case, the execution model executes the steps recursively, as follows:1. Original SQL statement issued.2. BEFORE row triggers fired.3. AFTER statement triggers fired by UPDATE inBEFORE row trigger.4. Statements of AFTER statement triggersexecuted.5. Integrity constraint on tables changed byAFTER statement triggers checked.6. Statements of BEFORE row triggers executed.7. Integrity constraint on tables changed byBEFORE row triggers checked.8. SQL statement executed.9. Integrity constraint from SQL statement checked.

- An important property of the execution model is that all actions and checks done as a result of a SQL statement must succeed.- If an exception is raised within a trigger, and the exception is not explicitly handled, all actions performed as a result of the original SQL statement, including the actions performed by fired triggers, are rolled back.- Thus, integrity constraints cannot be compromised by triggers.- The execution model takes into account integrity constraints and disallows triggers that violate declarative integrity constraints.- For example, in the previously outlined scenario, suppose that Steps 1 through 8 succeed; however, in Step 9 the integrity constraint is violated.- As a result of this violation, all changes made by the SQL statement (in Step 8), the fired BEFORE row trigger (in Step 6), and the fired AFTER statement trigger (in Step 4) are rolled back.Note: Be aware that triggers of different types are fired in a specific order. However,triggers of the same type for the same statement are not guaranteed to fire in anyspecific order. For example, all BEFORE ROW triggers for a single UPDATEstatement may not always fire in the same order. Design your applications not to relyon the firing order of multiple triggers of the same type.Data Access for Triggers When a trigger is fired, the tables referenced in the trigger action might be currently undergoing changes by SQL statements contained in other users' transactions. In all cases, the SQL statements executed within triggers follow the common rules used for standalone SQL statements. In particular, if an uncommitted transaction has modified values that a trigger being fired either needs to read (query) or write (update), the SQL statements in the body of the trigger being fired use the following guidelines: • Queries see the current read-consistent snapshot of referenced tables and any data changed within the same transaction. • Updates wait for existing data locks before proceeding.The following examples illustrate these points.ExampleAssume that the SALARY_CHECK trigger (body) includes the following SELECTstatement:SELECT minsal, maxsal INTO minsal, maxsal FROM salgrade WHERE job_classification = :new.job_classification;For this example, assume that transaction T1 includes an update to the MAXSALcolumn of the SALGRADE table. At this point, the SALARY_CHECK trigger is firedby a statement in transaction T2. The SELECT statement within the fired trigger(originating from T2) does not see the update by the uncommitted transaction T1, andthe query in the trigger returns the old MAXSAL value as of the read-consistent pointfor transaction T2.ExampleAssume the following definition of the TOTAL_SALARY trigger, a trigger tomaintain a derived column that stores the total salary of all members in a department:CREATE TRIGGER total_salaryAFTER DELETE OR INSERT OR UPDATE OF deptno, sal ON emp FOR EACH ROW BEGIN /* assume that DEPTNO and SAL are non-null fields */ IF DELETING OR (UPDATING AND :old.deptno !=:new.deptno) THEN UPDATE dept SET total_sal = total_sal - :old.sal WHERE deptno = :old.deptno; END IF; IF INSERTING OR (UPDATING AND :old.deptno !=:new.deptno) THEN UPDATE dept SET total_sal = total_sal + :new.sal WHERE deptno = :new.deptno; END IF; IF (UPDATING AND :old.deptno = :new.deptno AND :old.sal != :new.sal ) THEN UPDATE dept SET total_sal = total_sal - :old.sal + :new.sal WHERE deptno = :new.deptno; END IF; END;For this example, suppose that one user's uncommitted transaction includes an updateto the TOTAL_SAL column of a row in the DEPT table. At this point, theTOTAL_SALARY trigger is fired by a second user's SQL statement. Because theuncommitted transaction of the first user contains an update to a pertinent value inthe TOTAL_SAL column (in other words, a row lock is being held), the updatesperformed by the TOTAL_SALARY trigger are not executed until the transactionholding the row lock is committed or rolled back. Therefore, the second user waitsuntil the commit or rollback point of the first user's transaction.Storage for Triggers- For release 7.3, Oracle stores triggers in their compiled form, just like stored procedures.- When a CREATE TRIGGER statement commits, the compiled PL/SQL code, called P code (for pseudocode), is stored in the database and the source code of a trigger is flushed from the shared pool.

Execution of Triggers- Oracle internally executes a trigger using the same steps used for procedure execution.- The subtle and only difference is that a user automatically has the right to fire a trigger if he/she has the privilege to execute the triggering statement.- Other than this, triggers are validated and executed the same way as stored procedures.

Dependency Maintenance for Triggers

- Oracle automatically manages the dependencies of a trigger on the schema objects referenced in its trigger action.- The dependency issues for triggers are the same as dependency issues for stored procedures.- In releases earlier than 7.3, triggers were kept in memory. In release 7.3, triggers are treated like stored procedures; they are inserted in the data dictionary.- Like procedures, triggers are dependent on referenced objects. Oracle automatically manages dependencies among objects.

Using Database Triggers

• Enabling and Disabling Triggers

• Examples of Trigger Applications

This chapter discusses database triggers--procedures that are stored in the databaseand implicitly executed ("fired") when a table is modified. Topics include • creating triggers

• altering triggers • debugging triggers

• enabling and disabling triggers

• sample trigger applications

If you are using Trusted Oracle, see the Trusted Oracle7 Server Administrator's Guidefor more information about defining and using database triggers.Designing TriggersUse the following guidelines when designing triggers: • Use triggers to guarantee that when a specific operation is performed, related actions are performed. • Use database triggers only for centralized, global operations that should be fired for the triggering statement, regardless of which user or database application issues the statement. • Do not define triggers that duplicate the functionality already built into Oracle. For example, do not define triggers to enforce data integrity rules that can be easily enforced using declarative integrity constraints. • Limit the size of triggers (60 lines or fewer is a good guideline). If the logic for your trigger requires much more than 60 lines of PL/SQL code, it is better to include most of the code in a stored procedure, and call the procedure from the trigger. • Be careful not to create recursive triggers. For example, creating an AFTER UPDATE statement trigger on the EMP table that itself issues an UPDATE statement on EMP causes the trigger to fire recursively until it has run out of memory.Creating Triggers- Triggers are created using the CREATE TRIGGER command.- This command can be used with any interactive tool, such as SQL*Plus or Server Manager.- When using an interactive tool, a solitary slash ( / ) on the last line is used to activate the CREATE TRIGGER statement.- The following statement creates a trigger for the EMP table:CREATE TRIGGER print_salary_changesBEFORE DELETE OR INSERT OR UPDATE ON empFOR EACH ROWWHEN (new.empno > 0)DECLARE sal_diff number;BEGIN sal_diff := new.sal - old.sal; dbms_output.put('Old salary: ' || :old.sal); dbms_output.put(' New salary: ' || :new.sal); dbms_output.put_line(' Difference ' || sal_diff);END;/If you enter a SQL statement such asUPDATE emp SET sal = sal + 500.00 WHERE deptno = 10the trigger will fire once for each row that is updated, and it prints the new and oldsalaries, and the difference.The CREATE (or CREATE OR REPLACE) statement fails if any errors exist in thePL/SQL block.- The following sections use this example to illustrate the way that parts of a trigger are specified.Prerequisites- Before creating any triggers, while connected as SYS, submit the CATPROC.SQL script.- This script automatically runs all of the scripts required for, or used within, the procedural extensions to the Oracle Server.Additional Information: The location of this file is operating system dependent; seeyour platform-specific Oracle documentation.Naming Triggers- Trigger names must be unique with respect to other triggers in the same schema.- Trigger names do not have to be unique with respect to other schema objects such as tables, views, and procedures.- For example, a table and a trigger can have the same name (although, to avoid confusion, this is not recommended).The BEFORE/AFTER Options- Either the BEFORE or AFTER option must be used in the CREATE TRIGGER statement to specify exactly when the trigger body is fired in relation to the triggering statement being executed.- In a CREATE TRIGGER statement, the BEFORE or AFTER option is specified just before the triggering statement.- For example, the PRINT_SALARY_CHANGES trigger in the previous example is a BEFORE trigger.Note: - AFTER row triggers are slightly more efficient than BEFORE row triggers. - With BEFORE row triggers, affected data blocks must be read (logical read, not physical read) once for the trigger and then again for the triggering statement. - Alternatively, with AFTER row triggers, the data blocks need only be read once for both the triggering statement and the trigger.Triggering StatementThe triggering statement specifies • the type of SQL statement that fires the trigger body. The possible options include DELETE, INSERT, and UPDATE. One, two, or all three of these options can be included in the triggering statement specification. • the table associated with the trigger. Note that exactly one table (but not a view) can be specified in the triggering statement.For example, the PRINT_SALARY_CHANGES trigger fires after any DELETE,INSERT, or UPDATE on the EMP table. Any of the following statements wouldtrigger the PRINT_SALARY_CHANGES trigger given in the previous example:DELETE FROM emp;INSERT INTO emp VALUES ( . . . );INSERT INTO emp SELECT . . . FROM . . . ;UPDATE emp SET . . . ;Column List for UPDATE- If a triggering statement specifies UPDATE, an optional list of columns can be included in the triggering statement.- If you include a column list, the trigger is fired on an UPDATE statement only when one of the specified columns is updated.- If you omit a column list, the trigger is fired when any column of the associated table is updated.- A column list cannot be specified for INSERT or DELETE triggering statements.The previous example of the PRINT_SALARY_CHANGES trigger might haveincluded a column list in the triggering statement, as in. . . BEFORE DELETE OR INSERT OR UPDATE OF ename ON emp .. .FOR EACH ROW Option- The FOR EACH ROW option determines whether the trigger is a row trigger or a statement trigger.- If you specify FOR EACH ROW, the trigger fires once for each row of the table that is affected by the triggering statement.- The absence of the FOR EACH ROW option means that the trigger fires only once for each applicable statement, but not separately for each row affected by the statement.For example, you define the following trigger:CREATE TRIGGER log_salary_increaseAFTER UPDATE ON empFOR EACH ROWWHEN (new.sal > 1000)BEGIN INSERT INTO emp_log (emp_id, log_date, new_salary,action) VALUES (:new.empno, SYSDATE, :new.sal, 'NEW SAL');END;and then issue the SQL statementUPDATE emp SET sal = sal + 1000.0 WHERE deptno = 20;If there are five employees in department 20, the trigger will fire five times when thisstatement is issued, since five rows are affected.The following trigger fires only once for each UPDATE of the EMP table:CREATE TRIGGER log_emp_updateAFTER UPDATE ON empBEGIN INSERT INTO emp_log (log_date, action) VALUES (SYSDATE, 'EMP COMMISSIONS CHANGED');END;

The WHEN Clause

- Optionally, a trigger restriction can be included in the definition of a row trigger by specifying a Boolean SQL expression in a WHEN clause (a WHEN clause cannot be included in the definition of a statement trigger).- If included, the expression in the WHEN clause is evaluated for each row that the trigger affects.- If the expression evaluates to TRUE for a row, the trigger body is fired on behalf of that row.- However, if the expression evaluates to FALSE or NOT TRUE (that is, unknown, as with nulls) for a row, the trigger body is not fired for that row.- The evaluation of the WHEN clause does not have an effect on the execution of the triggering SQL statement (that is, the triggering statement is not rolled back if the expression in a WHEN clause evaluates to FALSE).- For example, in the PRINT_SALARY_CHANGES trigger, the trigger body would not be executed if the new value of EMPNO is zero, NULL, or negative.- In more realistic examples, you might test if one column value is less than another.- The expression in a WHEN clause of a row trigger can include correlation names, which are explained below.- The expression in a WHEN clause must be a SQL expression and cannot include a subquery.- You cannot use a PL/SQL expression (including user-defined functions) in the WHEN clause.The Trigger Body- The trigger body is a PL/SQL block that can include SQL and PL/SQL statements.- These statements are executed if the triggering statement is issued and the trigger restriction (if included) evaluates to TRUE.- The trigger body for row triggers has some special constructs that can be included in the code of the PL/SQL block: correlation names and the REFERENCING option, and the conditional predicates INSERTING, DELETING, and UPDATING.

Accessing Column Values in Row Triggers

- Within a trigger body of a row trigger, the PL/SQL code and SQL statements have access to the old and new column values of the current row affected by the triggering statement.- Two correlation names exist for every column of the table being modified: one for the old column value and one for the new column value.- Depending on the type of triggering statement, certain correlation names might not have any meaning. • A trigger fired by an INSERT statement has meaningful access to new column values only. Because the row is being created by the INSERT, the old values are null. • A trigger fired by an UPDATE statement has access to both old and new column values for both BEFORE and AFTER row triggers. • A trigger fired by a DELETE statement has meaningful access to old column values only. Because the row will no longer exist after the row is deleted, the new values are null.- The new column values are referenced using the NEW qualifier before the column name, while the old column values are referenced using the OLD qualifier before the column name.- For example, if the triggering statement is associated with the EMP table (with the columns SAL, COMM, etc.), you can include statements in the trigger body similar toIF :new.sal > 10000 . . .IF :new.sal < :old.sal . . .- Old and new values are available in both BEFORE and AFTER row triggers.- A NEW column value can be assigned in a BEFORE row trigger, but not in an AFTER row trigger (because the triggering statement takes effect before an AFTER row trigger is fired).- If a BEFORE row trigger changes the value of NEW.COLUMN, an AFTER row trigger fired by the same statement sees the change assigned by the BEFORE row trigger.- Correlation names can also be used in the Boolean expression of a WHEN clause.- A colon must precede the OLD and NEW qualifiers when they are used in a trigger's body, but a colon is not allowed when using the qualifiers in the WHEN clause or the REFERENCING option.The REFERENCING Option- The REFERENCING option can be specified in a trigger body of a row trigger to avoid name conflicts among the correlation names and tables that might be named "OLD" or "NEW".- Since this is rare, this option is infrequently used.- For example, assume you have a table named NEW with columns FIELD1 (number) and FIELD2 (character).- The following CREATE TRIGGER example shows a trigger associated with the NEW table that can use correlation names and avoid naming conflicts between the correlation names and the table name:CREATE TRIGGER PRINT_SALARY_CHANGESBEFORE UPDATE ON newREFERENCING new AS newestFOR EACH ROWBEGIN :newest.field2 := TO_CHAR (:newest.field1);END;Notice that the NEW qualifier is renamed to NEWEST using the REFERENCINGoption, and is then used in the trigger body.Conditional Predicates- If more than one type of DML operation can fire a trigger (for example, "ON INSERT OR DELETE OR UPDATE OF emp"), the trigger body can use the conditional predicates INSERTING, DELETING, and UPDATING to execute specific blocks of code, depending on the type of statement that fires the trigger. Assume this is the triggering statement:INSERT OR UPDATE ON empWithin the code of the trigger body, you can include the following conditions:IF INSERTING THEN . . . END IF;IF UPDATING THEN . . . END IF;The first condition evaluates to TRUE only if the statement that fired the trigger is anINSERT statement; the second condition evaluates to TRUE only if the statement thatfired the trigger is an UPDATE statement.- In an UPDATE trigger, a column name can be specified with an UPDATING conditional predicate to determine if the named column is being updated.- For example, assume a trigger is defined asCREATE TRIGGER . . .. . . UPDATE OF sal, comm ON emp . . .BEGIN. . . IF UPDATING ('SAL') THEN . . . END IF;END;- The code in the THEN clause executes only if the triggering UPDATE statement updates the SAL column.- The following statement would fire the above trigger and cause the UPDATING (sal) conditional predicate to evaluate to TRUE:UPDATE emp SET sal = sal + 100;

Error Conditions and Exceptions in the Trigger Body

- If a predefined or user-defined error condition or exception is raised during the execution of a trigger body, all effects of the trigger body, as well as the triggering statement, are rolled back (unless the error is trapped by an exception handler).- Therefore, a trigger body can prevent the execution of the triggering statement by raising an exception.- User-defined exceptions are commonly used in triggers that enforce complex security authorizations or integrity constraints.

Triggers and Handling Remote Exceptions

- A trigger that accesses a remote site cannot do remote exception handling if the network link is unavailable. For example:CREATE TRIGGER exampleAFTER INSERT ON empFOR EACH ROWBEGIN INSERT INTO emp@remote -- <- compilation failshere VALUES ('x'); -- when dblink isinaccessibleEXCEPTION WHEN OTHERS THEN INSERT INTO emp_log VALUES ('x');END;- A trigger is compiled when it is created.- Thus, if a remote site is unavailable when the trigger must compile, Oracle cannot validate the statement accessing the remote database, and the compilation fails.- The previous example exception statement cannot execute because the trigger does not complete compilation.- Because stored procedures are stored in a compiled form, the work-around for the above example is as follows:CREATE TRIGGER exampleAFTER INSERT ON empFOR EACH ROWBEGIN insert_row_proc;END;

CREATE PROCEDURE insert_row_proc

BEGIN INSERT INTO emp@remote VALUES ('x');EXCEPTION WHEN OTHERS THEN INSERT INTO emp_log VALUES ('x');END;- The trigger in this example compiles successfully and calls the stored procedure, which already has a validated statement for accessing the remote database; thus, when the remote INSERT statement fails because the link is down, the exception is caught.Restrictions on Creating Triggers- Coding a trigger requires some restrictions that are not required for standard PL/SQL blocks. The following sections discuss these restrictions.Valid SQL Statements in Trigger Bodies- The body of a trigger can contain DML SQL statements.- It can also contain SELECT statements, but they must be SELECT ... INTO ... statements or the SELECT statement in the definition of a cursor).- DDL statements are not allowed in the body of a trigger.- Also, no transaction control statements are allowed in a trigger. The commands ROLLBACK, COMMIT, and SAVEPOINT cannot be used.Note:- A procedure called by a trigger cannot execute the above transaction control statements because the procedure executes within the context of the trigger body.- Statements inside a trigger can reference remote objects.- However, pay special attention when calling remote procedures from within a local trigger; since if a timestamp or signature mismatch is found during execution of the trigger, the remote procedure is not executed and the trigger is invalidated.LONG and LONG RAW DatatypesLONG and LONG RAW datatypes in triggers are subject to the following restrictions: • A SQL statement within a trigger can insert data into a column of LONG or LONG RAW datatype. • If data from a LONG or LONG RAW column can be converted to a constrained datatype (such as CHAR and VARCHAR2), a LONG or LONG RAW column can be referenced in a SQL statement within a trigger. Note that the maximum length for these datatypes is 32000 bytes. • Variables cannot be declared using the LONG or LONG RAW datatypes.

• :NEW and :OLD cannot be used with LONG or LONG RAW columns.

References to Package Variables

- If an UPDATE or DELETE statement detects a conflict with a concurrent UPDATE, Oracle performs a transparent rollback to savepoint and restarts the update.- This can occur many times before the statement completes successfully.- Each time the statement is restarted, the BEFORE STATEMENT trigger is fired again.- The rollback to savepoint does not undo changes to any package variables referenced in the trigger.- The package should include a counter variable to detect this situation.Row Evaluation Order- A relational database does not guarantee the order of rows processed by a SQL statement.- Therefore, do not create triggers that depend on the order in which rows will be processed.- For example, do not assign a value to a global package variable in a row trigger if the current value of the global variable is dependent on the row being processed by the row trigger.- Also, if global package variables are updated within a trigger, it is best to initialize those variables in a BEFORE statement trigger.- When a statement in a trigger body causes another trigger to be fired, the triggers are said to be cascading.- Oracle allows up to 32 triggers to cascade at any one time.- However, you can effectively limit the number of trigger cascades using the initialization parameter OPEN_CURSORS, because a cursor must be opened for every execution of a trigger.Trigger Evaluation Order- Although any trigger can execute a sequence of operations either in-line or by calling procedures, using multiple triggers of the same type enhances database administration by permitting the modular installation of applications that have triggers on the same tables.- Oracle executes all triggers of the same type before executing triggers of a different type.- If you have multiple triggers of the same type on a single table, Oracle chooses an arbitrary order to execute these triggers.- Each subsequent trigger sees the changes made by the previously fired triggers.- Each trigger can see the old and new values.- The old values are the original values and the new values are the current values as set by the most recently fired UPDATE or INSERT trigger.- To ensure that multiple triggered actions occur in a specific order, you must consolidate these actions into a single trigger (for example, by having the trigger call a series of procedures).- You cannot open a database that contains multiple triggers of the same type if you are using any version of Oracle before release 7.1, nor can you open such a database if your COMPATIBLE initialization parameter is set to a version earlier than 7.1.0.Mutating and Constraining Tables- A mutating table is a table that is currently being modified by an UPDATE, DELETE, or INSERT statement, or a table that might need to be updated by the effects of a declarative DELETE CASCADE referential integrity constraint.- A constraining table is a table that a triggering statement might need to read either directly, for a SQL statement, or indirectly, for a declarative referential integrity constraint.- A table is mutating or constraining only to the session that issued the statement in progress.- Tables are never considered mutating or constraining for statement triggers unless the trigger is fired as the result of a DELETE CASCADE.- For all row triggers, or for statement triggers that were fired as the result of a DELETE CASCADE, there are two important restrictions regarding mutating and constraining tables.- These restrictions prevent a trigger from seeing an inconsistent set of data. • The SQL statements of a trigger cannot read from (query) or modify a mutating table of the triggering statement. • The statements of a trigger cannot change the PRIMARY, FOREIGN, or UNIQUE KEY columns of a constraining table of the triggering statement.- There is an exception to this restriction; BEFORE ROW and AFTER ROW triggers fired by a single row INSERT to a table do not treat that table as mutating or constraining.- Note that INSERT statements that may involve more than one row, such as INSERT INTO emp SELECT . . ., are not considered single row inserts, even if they only result in one row being inserted.Figure 9 - 1 illustrates the restriction placed on mutating tables.

Figure 9 - 1. Mutating Tables

- Notice that the SQL statement is executed for the first row of the table and then an AFTER ROW trigger is fired.- In turn, a statement in the AFTER ROW trigger body attempts to query the original table.- However, because the EMP table is mutating, this query is not allowed by Oracle.- If attempted, a runtime error occurs, the effects of the trigger body and triggering statement are rolled back, and control is returned to the user or application.Consider the following trigger:CREATE OR REPLACE TRIGGER emp_countAFTER DELETE ON EMPFOR EACH ROWDECLARE n INTEGER;BEGIN SELECT COUNT(*) INTO n FROM emp; DBMS_OUTPUT.PUT_LINE(' There are now ' || n || ' employees.');END;If the SQL statementDELETE FROM emp WHERE empno = 7499;is issued, the following error is returned:ORA-04091: table SCOTT.EMP is mutating, trigger/functionmay not see it- Oracle returns this error when the trigger fires since the table is mutating when the first row is deleted.- (Only one row is deleted by the statement, since EMPNO is a primary key, but Oracle has no way of knowing that.)- If you delete the line ``FOR EACH ROW'' from the trigger above, the trigger becomes a statement trigger, the table is not mutating when the trigger fires, and the trigger does output the correct data.- If you need to update a mutating or constraining table, you could use a temporary table, a PL/SQL table, or a package variable to bypass these restrictions.- For example, in place of a single AFTER row trigger that updates the original table, resulting in a mutating table error, you may be able to use two triggers--an AFTER row trigger that updates a temporary table, and an AFTER statement trigger that updates the original table with the values from the temporary table.- Declarative integrity constraints are checked at various times with respect to row triggers.- Because declarative referential integrity constraints are currently not supported between tables on different nodes of a distributed database, the constraining table restrictions do not apply to triggers that access remote nodes.- These restrictions are also not enforced among tables in the same database that are connected by loop-back database links.- A loop-back database link makes a local table appear remote by defining a SQL*Net path back to the database that contains the link.- You should not use loop-back database links to circumvent the trigger restrictions.- Such applications might behave unpredictably.- Trigger restrictions, which were implemented to prevent row triggers from seeing an inconsistent set of data, might be enforced on loop-back database links in future releases of Oracle.Who is the Trigger User?- If you issue the statement SELECT username FROM USER_USERSin a trigger, the name of the owner of the trigger is returned, not the name of user whois updating the table.Privileges Required to Create TriggersTo create a trigger in your schema, you must have the CREATE TRIGGER systemprivilege, and either • own the table specified in the triggering statement, or

• have the ALTER privilege for the table in the triggering statement, or

• have the ALTER ANY TABLE system privilege

• To create a trigger in another user's schema, you must have the CREATE ANY TRIGGER system privilege. With this privilege, the trigger can be created in any schema and can be associated with any user's table.Privileges for Referenced Schema Objects- The object privileges to the schema objects referenced in the trigger body must be granted to the trigger's owner explicitly (not via a role).- The statements in the trigger body operate under the privilege domain of the trigger's owner, not the privilege domain of the user issuing the triggering statement.When Triggers Are Compiled- In previous releases of the Oracle7 Server, triggers were basically like PL/SQL anonymous blocks, with the addition of the :NEW and :OLD capabilities.- A PL/SQL anonymous block is compiled each time it is loaded into memory. Compilation involves three stages: 1. syntax checking: PL/SQL syntax is checked and a parse tree is generated 2. semantic checking: type checking and further processing on the parse tree 3. code generation: the pcode is generated- The CREATE TRIGGER statement creates a trigger, and stores its source in the data dictionary.- In releases prior to 7.3, steps 1 and 2 are performed at CREATE TRIGGER time, so that syntactic and semantic errors can be reported back to the user who issued the CREATE TRIGGER command.- However, the compiler output is discarded. At execution time, the source for the trigger is parsed and executed just like an anonymous PL/SQL block.- In Oracle7 release 7.3, triggers are fully compiled when the CREATE TRIGGER command is issued, and the pcode is stored in the data dictionary.- Hence, firing the trigger no longer requires the opening of a shared cursor to run the trigger action. Instead, the trigger is executed directly.- If errors occur during the compilation of a trigger, the trigger is still created.- If a DML statement fires this trigger, the DML statement will fail.- (In both release 7.3 and releases 7.2 and earlier, runtime trigger errors always cause the DML statement to fail.) You can use the SHOW ERRORS command in SQL*Plus or Server Manager to see any compilation errors when you create a trigger, or you can SELECT the errors from the USER_ERRORS view.Dependencies- Compiled triggers have dependencies.- They become invalid if a depended-on object, such as a stored procedure or a function called from the trigger body, is modified.- Triggers that are invalidated for dependency reasons are recompiled when next invoked.You can examine the ALL_DEPENDENCIES view to see the dependencies for atrigger. For example, the statementSELECT NAME, REFERENCED_OWNER, REFERENCED_NAME,REFERENCED_TYPE FROM ALL_DEPENDENCIES WHERE OWNER = 'SCOTT' and TYPE = 'TRIGGER';shows the dependencies for the triggers in the SCOTT schema.Recompiling a Trigger- Use the ALTER TRIGGER command to recompile a trigger manually. For example, the commandALTER TRIGGER print_salary_changes COMPILE;recompiles the PRINT_SALARY_CHANGES triggerMigration Issues- Non-compiled triggers cannot be fired under compiled trigger releases (such as 7.3).- If upgrading from a non-compiled trigger release to a compiled trigger release, all existing triggers must be compiled.- The upgrade script cat73xx.sql invalidates all triggers so that they are automatically recompiled when first executed under the Oracle release 7.3 server. (The xx stands for a variable minor release number.)- Downgrading from 7.3 or later to a release prior to 7.3 requires that you execute the cat73xxd.sql downgrade script.- This handles portability issues between stored and non-stored trigger releases.Modifying a Trigger- Like a stored procedure, a trigger cannot be explicitly altered; it must be replaced with a new definition.- (The ALTER TRIGGER command is used only to recompile, enable or disable a trigger.).- When replacing a trigger, you must include the OR REPLACE option in the CREATE TRIGGER statement.- The OR REPLACE option is provided to allow a new version of an existing trigger to replace the older version without affecting any grants made for the original version of the trigger.- Alternatively, the trigger can be dropped using the DROP TRIGGER command, and you can rerun the CREATE TRIGGER command.- To drop a trigger, the trigger must be in your schema or you must have the DROP ANY TRIGGER system privilege.Enabling and Disabling TriggersA trigger can be in one of two distinct modes:enabledAn enabled trigger executes its trigger body if a triggering statement is issued and thetrigger restriction (if any) evaluates to TRUE.disabledA disabled trigger does not execute its trigger body, even if a triggering statement isissued and the trigger restriction (if any) evaluates to TRUE.Disabling TriggersYou might temporarily disable a trigger if • an object it references is not available

• you have to perform a large data load and want it to proceed quickly without firing triggers • you are reloading data- By default, triggers are enabled when first created.- Disable a trigger using the ALTER TRIGGER command with the DISABLE option.- For example, to disable the trigger named REORDER of the INVENTORY table, enter the following statement:ALTER TRIGGER reorder DISABLE;- All triggers associated with a table can be disabled with one statement using the ALTER TABLE command with the DISABLE clause and the ALL TRIGGERS option.- For example, to disable all triggers defined for the INVENTORY table, enter the following statement:ALTER TABLE inventory DISABLE ALL TRIGGERS;Enabling Triggers- By default, a trigger is automatically enabled when it is created; however, it can later be disabled.- Once you have completed the task that required the trigger to be disabled, re- enable the trigger so it fires when appropriate.- Enable a disabled trigger using the ALTER TRIGGER command with the ENABLE option.- To enable the disabled trigger named REORDER of the INVENTORY table, enter the following statement:ALTER TRIGGER reorder ENABLE;- All triggers defined for a specific table can be enabled with one statement using the ALTER TABLE command with the ENABLE clause with the ALL TRIGGERS option.- For example, to enable all triggers defined for the INVENTORY table, enter the following statement:ALTER TABLE inventory ENABLE ALL TRIGGERS;Privileges Required to Enable and Disable Triggers- To enable or disable triggers using the ALTER TABLE command, you must either own the table, have the ALTER object privilege for the table, or have the ALTER ANY TABLE system privilege.- To enable or disable triggers using the ALTER TRIGGER command, you must own the trigger or have the ALTER ANY TRIGGER system privilege.Listing Information About TriggersThe following data dictionary views reveal information about triggers: • USER_TRIGGERS

• ALL_TRIGGERS

• DBA_TRIGGERSFor example, assume the following statement was used to create the REORDERtrigger:CREATE TRIGGER reorderAFTER UPDATE OF parts_on_hand ON inventoryFOR EACH ROWWHEN(new.parts_on_hand < new.reorder_point)DECLARE x NUMBER;BEGIN SELECT COUNT(*) INTO x FROM pending_orders WHERE part_no = :new.part_no; IF x = 0 THEN INSERT INTO pending_orders VALUES (:new.part_no, :new.reorder_quantity, sysdate); END IF;END;The following two queries return information about the REORDER trigger:SELECT trigger_type, triggering_event, table_name FROM user_triggers WHERE name = 'REORDER';

TYPE TRIGGERING_STATEMENT TABLE_NAME

TRIGGER_BODY--------------------------------------------DECLARE x NUMBER;BEGIN SELECT COUNT(*) INTO x FROM pending_orders WHERE part_no = :new.part_no; IF x = 0 THEN INSERT INTO pending_orders VALUES (:new.part_no, :new.reorder_quantity, sysdate); END IF;END;Examples of Trigger ApplicationsYou can use triggers in a number of ways to customize information management in anOracle database. For example, triggers are commonly used to • provide sophisticated auditing

• prevent invalid transactions

integrity constraints or across nodes in a distributed database) • enforce complex business rules

• enforce complex security authorizations

• provide transparent event logging

• automatically generate derived column values

This section provides an example of each of the above trigger applications. Theseexamples are not meant to be used as is, but are provided to assist you in designingyour own triggers.Auditing with Triggers- Triggers are commonly used to supplement the built-in auditing features of Oracle.- Although triggers can be written to record information similar to that recorded by the AUDIT command, triggers should be used only when more detailed audit information is required.- For example, use triggers to provide value-based auditing on a per-row basis for tables.- Sometimes, the Oracle AUDIT command is considered a security audit facility, while triggers can provide financial audit facility.- When deciding whether to create a trigger to audit database activity, consider what Oracle's auditing features provide, compared to auditing defined by triggers.DML as well as DDL auditingStandard auditing options permit auditing of DML and DDL statements regarding alltypes of schema objects and structures. Comparatively, triggers only permit auditingof DML statements issued against tables.Centralized audit trailAll database audit information is recorded centrally and automatically using theauditing features of Oracle.Declarative methodAuditing features enabled using the standard Oracle features are easier to declare andmaintain, and less prone to errors when compared to auditing functions defined bytriggers.Auditing options can be auditedAny changes to existing auditing options can also be audited to guard againstmalicious database activity.Session and execution time auditingUsing the database auditing features, records can be generated once every time anaudited statement is issued (BY ACCESS) or once for every session that issues anaudited statement (BY SESSION). Triggers cannot audit by session; an audit record isgenerated each time a trigger-audited table is referenced.Auditing of unsuccessful data accessDatabase auditing can be set to audit when unsuccessful data access occurs. However,any audit information generated by a trigger is rolled back if the triggering statementis rolled back.Sessions can be auditedConnections and disconnections, as well as session activity (physical I/Os, logicalI/Os, deadlocks, etc.), can be recorded using standard database auditing.- When using triggers to provide sophisticated auditing, AFTER triggers are normally used.- By using AFTER triggers, auditing information is recorded after the triggering statement is subjected to any applicable integrity constraints, preventing cases where the audit processing is carried out unnecessarily for statements that generate exceptions to integrity constraints.- When to use AFTER row vs. AFTER statement triggers depends on the information being audited.- For example, row triggers provide value-based auditing on a per-row basis for tables.- Triggers can also require the user to supply a "reason code" for issuing the audited SQL statement, which can be useful in both row and statement-level auditing situations.- The following example demonstrates a trigger that audits modifications to the EMP table on a per-row basis.- It requires that a "reason code" be stored in a global package variable before the update.ExampleThis trigger demonstrates • how triggers can be used to provide value-based auditing

• how to use public package variables

Comments within the code explain the functionality of the trigger.CREATE TRIGGER audit_employeeAFTER INSERT OR DELETE OR UPDATE ON empFOR EACH ROWBEGIN/* AUDITPACKAGE is a package with a public package variable REASON. REASON could be set by the application by a command such as EXECUTE AUDITPACKAGE.SET_REASON(reason_string). Note that a package variable has state for the duration of a session and that each session has a separate copy of all package variables. */

IF auditpackage.reason IS NULL THEN

raise_application_error(-20201, 'Must specify reason' || ' with AUDITPACKAGE.SET_REASON(reason_string)');END IF;/* If the above conditional evaluates to TRUE, the user-specified error number and message is raised, the trigger stops execution, and the effects of the triggering statement are rolled back. Otherwise, a new row is inserted into the predefined auditing table named AUDIT_EMPLOYEE containing the existing and new values of the EMP table and the reason code defined by the REASON variable of AUDITPACKAGE. Note that the "old" values are NULL if triggering statement is an INSERT and the "new" values are NULL if the triggering statement is a DELETE. */

INSERT INTO audit_employee VALUES

(:old.ssn, :old.name, :old.job_classification,:old.sal, :new.ssn, :new.name, :new.job_classification,:new.sal, auditpackage.reason, user, sysdate );END;- Optionally, you can also set the reason code back to NULL if you wanted to force the reason code to be set for every update.- The following simple AFTER statement trigger sets the reason code back to NULL after the triggering statement is executed:CREATE TRIGGER audit_employee_resetAFTER INSERT OR DELETE OR UPDATE ON empBEGIN auditpackage.set_reason(NULL);END;- Notice that the previous two triggers are both fired by the same type of SQL statement.- However, the AFTER row trigger is fired once for each row of the table affected by the triggering statement, while the AFTER statement trigger is fired only once after the triggering statement execution is completed.- Another example of using triggers to do auditing is shown below.- This trigger tracks changes being made to the EMP table, and stores this information in AUDIT_TABLE and AUDIT_TABLE_VALUES.CREATE OR REPLACE TRIGGER audit_emp AFTER INSERT OR UPDATE OR DELETE ON emp FOR EACH ROW DECLARE time_now DATE; terminal CHAR(10); BEGIN

-- and for SAL and DEPTNO, record old and new

ELSIF UPDATING ('DEPTNO') THEN

INSERT INTO audit_table_values VALUES (audit_seq.CURRVAL, 'DEPTNO', :old.deptno, :new.deptno); END IF; END IF; END;/Integrity Constraints and Triggers- Triggers and declarative integrity constraints can both be used to constrain data input.- However, triggers and integrity constraints have significant differences.- Declarative integrity constraints are statements about the database that are always true.- A constraint applies to existing data in the table and any statement that manipulates the table.- Triggers constrain what a transaction can do.- A trigger does not apply to data loaded before the definition of the trigger; therefore, it is not known if all data in a table conforms to the rules established by an associated trigger.- Although triggers can be written to enforce many of the same rules supported by Oracle's declarative integrity constraint features, triggers should only be used to enforce complex business rules that cannot be defined using standard integrity constraints.- The declarative integrity constraint features provided with Oracle offer the following advantages when compared to constraints defined by triggers:Centralized integrity checksAll points of data access must adhere to the global set of rules defined by the integrityconstraints corresponding to each schema object.Declarative methodConstraints defined using the standard integrity constraint features are much easier towrite and are less prone to errors when compared with comparable constraints definedby triggers.While most aspects of data integrity can be defined and enforced using declarativeintegrity constraints, triggers can be used to enforce complex business constraints notdefinable using declarative integrity constraints. For example, triggers can be used toenforce • UPDATE and DELETE SET NULL, and UPDATE and DELETE SET DEFAULT referential actions • referential integrity when the parent and child tables are on different nodes of a distributed database • complex check constraints not definable using the expressions allowed in a CHECK constraintEnforcing Referential Integrity Using Triggers- Many cases of referential integrity can be enforced using triggers.- However, only use triggers when you want to enforce the UPDATE and DELETE SET NULL (when referenced data is updated or deleted, all associated dependent data is site to NULL), and UPDATE and DELETE SET DEFAULT (when referenced data is updated or deleted, all associated dependent data is set to a default value) referential actions, or when you want to enforce referential integrity between parent and child tables on different nodes of a distributed database.- When using triggers to maintain referential integrity, declare the PRIMARY (or UNIQUE) KEY constraint in the parent table.- If referential integrity is being maintained between a parent and child table in the same database, you can also declare the foreign key in the child table, but disable it; this prevents the corresponding PRIMARY KEY constraint from being dropped (unless the PRIMARY KEY constraint is explicitly dropped with the CASCADE option).To maintain referential integrity using triggers: • A trigger must be defined for the child table that guarantees values inserted or updated in the foreign key correspond to values in the parent key. • One or more triggers must be defined for the parent table. These triggers guarantee the desired referential action (RESTRICT, CASCADE, or SET NULL) for values in the foreign key when values are updated or deleted in the parent key. No action is required for inserts into the parent table (no dependent foreign keys exist).- The following sections provide examples of the triggers necessary to enforce referential integrity.- The EMP and DEPT table relationship is used in these examples.- Several of the triggers include statements that lock rows (SELECT ... FOR UPDATE).- This operation is necessary to maintain concurrency as the rows are being processed.Foreign Key Trigger for Child Table- The following trigger guarantees that before an INSERT or UPDATE statement affects a foreign key value, the corresponding value exists in the parent key.- The mutating table exception included in the example below allows this trigger to be used with the UPDATE_SET_DEFAULT and UPDATE_CASCADE triggers.- This exception can be removed if this trigger is used alone.CREATE TRIGGER emp_dept_checkBEFORE INSERT OR UPDATE OF deptno ON empFOR EACH ROW WHEN (new.deptno IS NOT NULL)

-- Verify parent key. If not found, raise user-

specified -- error number and message. If found, close cursor -- before allowing triggering statement to complete. IF dummy_cursor%NOTFOUND THEN RAISE invalid_department;

ELSE RAISE valid_department; END IF; CLOSE dummy_cursor;EXCEPTION WHEN invalid_department THEN CLOSE dummy_cursor; raise_application_error(-20000, 'InvalidDepartment' || ' Number' || TO_CHAR(:new.deptno)); WHEN valid_department THEN CLOSE dummy_cursor; WHEN mutating_table THEN NULL;END;UPDATE and DELETE RESTRICT Trigger for the Parent Table - The following trigger is defined on the DEPT table to enforce the UPDATE and DELETE RESTRICT referential action on the primary key of the DEPT table:CREATE TRIGGER dept_restrictBEFORE DELETE OR UPDATE OF deptno ON deptFOR EACH ROW

EXCEPTION WHEN employees_present THEN CLOSE dummy_cursor; raise_application_error(-20001, 'Employees Presentin' || ' Department ' || TO_CHAR(:old.deptno)); WHEN employees_not_present THEN CLOSE dummy_cursor;END;Note: - This trigger will not work with self-referential tables (that is, tables with both the primary/unique key and the foreign key). - Also, this trigger does not allow triggers to cycle (such as, A fires B fires A).UPDATE and DELETE SET NULL Triggers for Parent Table- The following trigger is defined on the DEPT table to enforce the UPDATE and DELETE SET NULL referential action on the primary key of the DEPT table:CREATE TRIGGER dept_set_nullAFTER DELETE OR UPDATE OF deptno ON deptFOR EACH ROW

-- Before a row is deleted from DEPT or the primary key

-- (DEPTNO) of DEPT is updated, set all corresponding-- dependent foreign key values in EMP to NULL.BEGIN IF UPDATING AND :OLD.deptno != :NEW.deptno OR DELETINGTHEN UPDATE emp SET emp.deptno = NULL WHERE emp.deptno = :old.deptno; END IF;END;DELETE Cascade Trigger for Parent Table- The following trigger on the DEPT table enforces the DELETE CASCADE referential action on the primary key of the DEPT table:CREATE TRIGGER dept_del_cascadeAFTER DELETE ON deptFOR EACH ROW

-- Before a row is deleted from DEPT, delete all

-- rows from the EMP table whose DEPTNO is the same as-- the DEPTNO being deleted from the DEPT table.BEGIN DELETE FROM emp WHERE emp.deptno = :old.deptno;END;Note: Typically, the code for DELETE cascade is combined with the code forUPDATE SET NULL or UPDATE SET DEFAULT to account for both updates anddeletes.UPDATE Cascade Trigger for Parent Table The following trigger ensures that if adepartment number is updated in the DEPT table, this change is propagated todependent foreign keys in the EMP table:-- Generate a sequence number to be used as a flag for-- determining if an update has occurred on a column.CREATE SEQUENCE update_sequence INCREMENT BY 1 MAXVALUE 5000 CYCLE;

CREATE PACKAGE integritypackage AS

CREATE or replace PACKAGE BODY integritypackage AS

CREATE TRIGGER dept_cascade1 BEFORE UPDATE OF deptno ON

deptDECLARE dummy NUMBER;

-- Before updating the DEPT table (this is a statement

-- trigger), generate a new sequence number and assign-- it to the public variable UPDATESEQ of a user-defined-- package named INTEGRITYPACKAGE.BEGIN SELECT update_sequence.NEXTVAL INTO dummy FROM dual; integritypackage.updateseq := dummy;END;CREATE TRIGGER dept_cascade2 AFTER DELETE OR UPDATE OF deptno ON dept FOR EACH ROW

-- For each department number in DEPT that is updated,

-- cascade the update to dependent foreign keys in the-- EMP table. Only cascade the update if the child row-- has not already been updated by this trigger.BEGIN IF UPDATING THEN UPDATE emp SET deptno = :new.deptno, update_id = integritypackage.updateseq /*from1st*/ WHERE emp.deptno = :old.deptno AND update_id IS NULL; /* only NULL if not updated by the 3rd trigger fired by this same triggering statement */ END IF; IF DELETING THEN

-- Before a row is deleted from DEPT, delete all

-- rows from the EMP table whose DEPTNO is the same as -- the DEPTNO being deleted from the DEPT table. DELETE FROM emp WHERE emp.deptno = :old.deptno; END IF;END;CREATE TRIGGER dept_cascade3 AFTER UPDATE OF deptno ONdeptBEGIN UPDATE emp SET update_id = NULL WHERE update_id = integritypackage.updateseq;END;Note: Because this trigger updates the EMP table, the EMP_DEPT_CHECK trigger,if enabled, is also fired. The resulting mutating table error is trapped by theEMP_DEPT_CHECK trigger. You should carefully test any triggers that require errortrapping to succeed to ensure that they will always work properly in yourenvironment.Enforcing Complex Check Constraints- Triggers can enforce integrity rules other than referential integrity.- For example, this trigger performs a complex check before allowing the triggering statement to execute. Comments within the code explain the functionality of the trigger.CREATE TRIGGER salary_checkBEFORE INSERT OR UPDATE OF sal, job ON empFOR EACH ROWDECLARE minsal NUMBER; maxsal NUMBER; salary_out_of_range EXCEPTION;BEGIN

/* Retrieve the minimum and maximum salary for the

employee's new job classification from the SALGRADE table into MINSAL and MAXSAL. */

SELECT minsal, maxsal INTO minsal, maxsal FROM salgrade

WHERE job_classification = :new.job;

/* If the employee's new salary is less than or greater

than the job classification's limits, the exception is raised. The exception message is returned and the pending INSERT or UPDATE statement that fired the trigger is rolled back. */

IF (:new.sal < minsal OR :new.sal > maxsal) THEN

RAISE salary_out_of_range; END IF;EXCEPTION WHEN salary_out_of_range THEN raise_application_error (-20300, 'Salary '||TO_CHAR(:new.sal)||' out of range for' ||'job classification '||:new.job ||' for employee '||:new.name); WHEN NO_DATA_FOUND THEN raise_application_error(-20322, 'Invalid Job Classification ' ||:new.job_classification);END;Complex Security Authorizations and Triggers- Triggers are commonly used to enforce complex security authorizations for table data.- Only use triggers to enforce complex security authorizations that cannot be defined using the database security features provided with Oracle.- For example, a trigger can prohibit updates to salary data of the EMP table during weekends, holidays, and non-working hours.When using a trigger to enforce a complex security authorization, it is best to use aBEFORE statement trigger. Using a BEFORE statement trigger has these benefits: • The security check is done before the triggering statement is allowed to execute so that no wasted work is done by an unauthorized statement. • The security check is performed only once for the triggering statement, not for each row affected by the triggering statement.ExampleThis example shows a trigger used to enforce security. The comments within the codeexplain the functionality of the trigger.CREATE TRIGGER emp_permit_changesBEFORE INSERT OR DELETE OR UPDATE ON empDECLARE dummy INTEGER; not_on_weekends EXCEPTION; not_on_holidays EXCEPTION; non_working_hours EXCEPTION;BEGIN /* check for weekends */ IF (TO_CHAR(sysdate, 'DY') = 'SAT' OR TO_CHAR(sysdate, 'DY') = 'SUN') THEN RAISE not_on_weekends; END IF; /* check for company holidays */ SELECT COUNT(*) INTO dummy FROM company_holidays WHERE TRUNC(day) = TRUNC(sysdate); /* TRUNC gets rid of time parts of dates */ IF dummy > 0 THEN RAISE not_on_holidays; END IF; /* Check for work hours (8am to 6pm) */ IF (TO_CHAR(sysdate, 'HH24') < 8 OR TO_CHAR(sysdate, 'HH24') > 18) THEN RAISE non_working_hours; END IF;EXCEPTION WHEN not_on_weekends THEN raise_application_error(-20324,'May not change ' ||'employee table during the weekend'); WHEN not_on_holidays THEN raise_application_error(-20325,'May not change ' ||'employee table during a holiday'); WHEN non_working_hours THEN raise_application_error(-20326,'May not change ' ||'emp table during non-working hours');END;Transparent Event Logging and TriggersTriggers are very useful when you want to transparently perform a related change inthe database following certain events.ExampleThe REORDER trigger example shows a trigger that reorders parts as necessarywhen certain conditions are met (that is, a triggering statement is issued and thePARTS_ON_HAND value is less than the REORDER_POINT value).Derived Column Values and TriggersTriggers can derive column values automatically based upon a value provided by anINSERT or UPDATE statement. This type of trigger is useful to force values inspecific columns that depend on the values of other columns in the same row.BEFORE row triggers are necessary to complete this type of operation because • the dependant values must be derived before the insert or update occurs so that the triggering statement can use the derived values. • the trigger must fire for each row affected by the triggering INSERT or UPDATE statement.ExampleThe following example illustrates how a trigger can be used to derive new columnvalues for a table whenever a row is inserted or updated. Comments within the codeexplain its functionality.BEFORE INSERT OR UPDATE OF ename ON emp

/* Before updating the ENAME field, derive the values for

the UPPERNAME and SOUNDEXNAME fields. Users should be restricted from updating these fields directly. */FOR EACH ROW

How Oracle Stores Procedures and Packages

When you create a procedure or package, Oracle automatically performs these steps: 1. Compiles the procedure or package. 2. Stores the compiled code in memory. 3. Stores the procedure or package in the database.Compiling Procedures and PackagesThe PL/SQL compiler compiles the source code. The PL/SQL compiler is part of thePL/SQL engine contained in Oracle. If an error occurs during compilation, a messageis returned.Storing the Compiled Code in Memory- Oracle caches the compiled procedure or package in the shared pool of the SGA. This allows the code to be executed quickly and shared among many users.- The compiled version of the procedure or package remains in the shared pool according to the modified least-recently-used algorithm used by the shared pool, even if the original caller of the procedure terminates his/her session.Storing Procedures or Packages in DatabaseAt creation and compile time, Oracle automatically stores the following informationabout a procedure or package in the database:

object nameOracle uses this name to identify the procedure or package. You specify this name inthe CREATE PROCEDURE, CREATE FUNCTION, CREATE PACKAGE, orCREATE PACKAGE BODY statement.source code and parse treeThe PL/SQL compiler parses the source code and produces a parsed representation ofthe source code, called a parse tree.pseudocode (P code)The PL/SQL compiler generates the pseudocode, or P code, based on the parsed code.The PL/SQL engine executes this when the procedure or package is invoked.error messagesOracle might generate errors during the compilation of a procedure or package.- To avoid unnecessary recompilation of a procedure or package, both the parse tree and the P code of an object are stored in the database.- This allows the PL/SQL engine to read the compiled version of a procedure or package into the shared pool buffer of the SGA when it is invoked and not currently in the SGA.- The parse tree is used when the code calling the procedure is compiled.- All parts of database procedures are stored in the data dictionary (which is in the SYSTEM tablespace) of the corresponding database.- The database administrator should plan the size of the SYSTEM tablespace, keeping in mind that all stored procedures require space in this tablespace.